JPH11175032A - Display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To always keep the sampling phase of a video signal to the optimum state. SOLUTION: The video signal from an input terminal 1 for video signal is supplied to switching elements X1, X2...Xn through a sample-and-hold circuit 2. These switching elements X1, X2...Xn are driven based on horizontal driving signals to be successively shifted, for example, for every pixel clock from a horizontal scanner circuit 3. Then, for example, a horizontal driving signal hn to be supplied from the circuit 3 to a final switching element Xn is taken out to an output terminal 6 through a buffer amplifier 6. Moreover, the horizontal driving signal hn taken out to the terminal 7 is, for example, supplied to the sample-and-hold circuit 2 through a level shifting circuit 8 and the phase of the video signal is controlled so that the samplings phase of the video signal is matched with phases of horizontal driving signals h1, h2...hn.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device suitable for use in displaying video signals using, for example, liquid crystal.

[0002]

2. Description of the Related Art For example, a configuration as shown in FIG. 3 is used as a display device for displaying a video signal using a liquid crystal. That is, in FIG. 3, the signal lines H1, H2... Hn, and V1, V
2... Vm are wired, and these signal lines H1, H2.
.. Cm are provided at the intersections of Hn and V1, V2... Vm via switching elements S11, S12. Note that n is the number of pixels in the horizontal direction, and m is the number of pixels in the vertical direction.

An input terminal 31 for a video signal is provided. The video signal from the input terminal 31 is supplied to the switching elements X1, X2,... Xn through a sampling hold (S / H) circuit 32 described later. The switching elements X1, X2,..., Xn are driven in accordance with a horizontal drive signal from the horizontal scanner circuit 33 which is sequentially shifted, for example, every pixel clock. As a result, video signals from the sampling and holding circuit 32 are sequentially supplied to the signal lines H1, H2,.

That is, the above-mentioned horizontal scanner circuit 33 has a start signal HS as shown in FIGS.
T and the pixel clock signal HCK are supplied. The start signal HST described above is generated by the pixel clock signal HCK.
Are sequentially shifted. As a result, horizontal drive signals h1, h2,... Hn as shown in FIG. These horizontal drive signals h1, h2,.
The switching elements X1, X2,... Xn are driven according to n.

Further, the signals supplied to the signal lines H1, H2,... Hn are connected to the switching elements S11, S12,.
supplied to nm. These switching elements S11, S12
.. Sm are driven according to vertical drive signals sequentially shifted, for example, every horizontal scanning period, from the vertical scanner circuit 34 supplied via signal lines V1, V2. As a result, the signal lines H1, H2,.
The signals supplied to Hn are sequentially applied to the liquid crystal display elements C11, C12.
..Supplied to Cnm.

As described above, the signals of the respective pixels of the video signal supplied to the input terminal 31 are respectively applied to the liquid crystal display element C1.
1, C12... Cnm, and a video signal is displayed. This display is rewritten, for example, on a field-by-field basis, so that a moving image is displayed.

[0007]

By the way, in the above-described apparatus, the video signal supplied to the input terminal 31 is supplied to the sampling and holding circuit 32, so that the signal to each signal line H1, H2. Supply is carried out smoothly. That is, when such a sampling hold is not performed, for example, the average value of the signal for each pixel is displayed, and the outline of the subject is blurred, and the displayed color is changed particularly in the color display. There is also the danger that they will be lost.

Therefore, in the above-described device, for example, a timing generation circuit 35 is provided. Then, the pixel clock signal HCK and the horizontal start signal HST from the timing generation circuit 35 are supplied to the horizontal scanner circuit 33,
A horizontal synchronization signal and a vertical start signal (not shown) are supplied to a vertical scanner circuit 34, and a timing signal ENB synchronized with the above-described pixel clock signal HCK is supplied to a sampling and holding circuit 32.

As a result, for example, in the horizontal scanner circuit 33, horizontal drive signals h1, h2,... Hn which are sequentially shifted for each of the above-mentioned pixel clock signals HCK are formed. In the sampling and holding circuit 32, for example, at each timing of the above-described pixel clock signal HCK, for example, FIG.
The sampling and holding of the video signal is performed as shown in D of FIG. 7, and the sampled and held video signal is supplied to the switching elements X1, X2,.

However, in the above apparatus, the phase of the pixel clock signal HCK and the horizontal drive signals h1, h2,.
The phases of n are not perfectly matched. This is because the horizontal drive signals h1, h2,.
The phase of hn may lag behind the pixel clock signal HCK. On the other hand, the sampling of the video signal by the sampling and holding circuit 32 is performed, for example, in accordance with the pixel clock signal HCK.

For this reason, in the above-described device, for example, the horizontal drive signal h1 and the horizontal drive signal h1 delayed from the pixel clock signal HCK as shown in FIG. h2... hn may be formed. On the other hand, the sampling hold circuit 32
Is sampled in accordance with the pixel clock signal HCK as shown in D of FIG.
The phase of the video signal and the phase of the horizontal drive signal do not match, and good display cannot be performed.

That is, for example, with respect to a video signal sampled as shown in FIG.
When the switching elements X1 and X2 are driven by the horizontal drive signals h1 and h2 as shown in FIG.
Is changed as shown by D and E in the figure, and finally the voltages as shown by v1 and v2 in the figure are held. As a result, for example, one sampled video signal is held on the two signal lines H1 and H2, and the horizontal resolution is degraded.

Accordingly, in the above-described apparatus, the horizontal drive signals h1, h2,.
If n is formed with a delay, the sampling of the video signal and the phases of the horizontal drive signals h1, h2... hn become inconsistent, and the horizontal resolution is degraded.

Therefore, in the conventional apparatus, for example, a phase adjusting (φ) means 36 is provided inside the sampling and holding circuit 32 to adjust the sampling phase with respect to the pixel clock signal HCK so that the sampling of the video signal and the horizontal driving signal are performed. The phases of h1, h2,... hn are matched.

However, in the above-described apparatus, for example, the delay time is not constant in, for example, the horizontal scanner circuit 33. For example, it is necessary to make adjustments for each display device, and an enormous amount of time is required for the adjustment. Further, the delay time is gradually changed depending on, for example, the elapsed time from the start. Therefore, even if the above-described phase adjustment is performed, there is a possibility that the sampling of the video signal and the phases of the horizontal drive signals h1, h2,...

This application has been made in view of such a point, and the problem to be solved is that in the conventional apparatus, it is necessary to adjust the sampling phase for each display device, for example. In addition, this phase is gradually changed depending on the elapsed time or the like, and there is a possibility that the sampling of the video signal and the phase of the horizontal drive signal may become inconsistent.

[0017]

According to the present invention, an arbitrary drive signal from a scanner circuit is taken out to control the sampling phase of a video signal. The sampling phase of the video signal can be set to an optimum state, that is, the adjustment of the sampling phase can be made unadjusted, and a good video signal can always be displayed.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention relates to a display device in which display elements are provided in a horizontal and vertical matrix, and arbitrary sampled video signals are sequentially supplied to the display elements to perform display. A scanner circuit for sequentially supplying video signals to the horizontal display elements is built in, and means for extracting an arbitrary drive signal from the scanner circuit is provided. The signal sampling phase is controlled.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of an example of a display device to which the present invention is applied.

In FIG. 1, signal lines H1, H2... Hn, and V1,.
V2... Vm are wired, and these signal lines H1, H2
, Hn and V1, V2,..., Vm are provided with liquid crystal display elements C11, C12,. Note that n is the number of pixels in the horizontal direction, and m is the number of pixels in the vertical direction.

An input terminal 1 for a video signal is provided. The video signal from the input terminal 1 is supplied to switching elements X1, X2,... Xn through a sampling and holding (S / H) circuit 2 to be described later. The switching elements X1, X2,..., Xn are driven according to a horizontal drive signal from the horizontal scanner circuit 3 which is sequentially shifted, for example, every pixel clock. As a result, the video signals from the sampling and holding circuit 2 are sequentially transferred to the signal line H1.
, H2... Hn.

Further, the signals supplied to the signal lines H1, H2,..., Hn are converted into switching elements S11, S12,.
Supplied to These switching elements S11, S12
.. Sm are driven according to vertical drive signals sequentially shifted, for example, every horizontal scanning period, from the vertical scanner circuit 4 supplied via signal lines V1, V2,. As a result, the signal lines H1, H2,.
Are sequentially supplied to the liquid crystal display elements C11, C12,.
Cnm.

As described above, the signal of each pixel of the video signal supplied to the input terminal 1 is applied to the liquid crystal display element C11,
C12... Cnm are supplied to display video signals. This display is rewritten, for example, on a field-by-field basis, so that a moving image is displayed.

Further, the above-mentioned horizontal scanner circuit 3 includes:
For example, a start signal HST as shown in FIGS. 2A and 2B from the timing generation circuit 5 and a pixel clock signal HCK.
Is supplied. The start signal HST is sequentially shifted by the pixel clock signal HCK. Thereby, for example, the horizontal drive signal h1, as shown in FIG.
h2... hn are formed. The switching elements X1, X2,..., Xn are driven according to these horizontal drive signals h1, h2,.

In this apparatus, for example, a horizontal drive signal hn supplied from the horizontal scanner circuit 3 to the last-stage switching element Xn is taken out to the output terminal 7 through the buffer amplifier 6.

Further, the horizontal drive signal hn taken out from the output terminal 7 is supplied to the sampling and holding circuit 2 through, for example, a level shift circuit 8. In accordance with the horizontal drive signal hn, the phase adjusting (.phi.) Means 9 built in the sampling and holding circuit 2 is adjusted to, for example, the sampling phase of the video signal and the horizontal drive signals h1 and h.
The sampling phase of the video signal is controlled so that the phases of 2... Hn coincide.

That is, in FIG. 2, before the sampling phase is adjusted, the video signal is sampled at a timing shown in D of FIG. On the other hand, by controlling the sampling phase so that the sampling coincides with the horizontal drive signal hn, for example, after adjusting the sampling phase, the video signal is adjusted at the timing shown in FIG. Will be sampled.

That is, in this apparatus, the sampling phase is controlled so as to coincide with, for example, the horizontal drive signal hn at the last stage of the horizontal scanner circuit 3. As a result, the sampling of the video signal and the horizontal drive signals h1, h2,.
The phase of hn is always coincident, for example, the adjustment for each display device becomes unnecessary, and the control is performed following changes due to elapsed time.

Therefore, in this apparatus, by taking out an arbitrary drive signal from the scanner circuit and controlling the sampling phase of the video signal, the sampling phase of the video signal can always be set to the optimum state. Adjustment can be eliminated,
A good video signal can always be displayed.

Thus, in the conventional apparatus, for example, it is necessary to adjust the sampling phase for each display device, and this phase is gradually changed by the elapsed time or the like. According to the present invention, there is a problem that the phase of the sampling of the horizontal drive signal and the phase of the horizontal drive signal may be inconsistent. However, according to the present invention, these problems can be easily solved.

In the above-described apparatus, since the phase variation among the horizontal drive signals h1, h2,... Hn is small, the sampling phase can be controlled by taking out an arbitrary drive signal among them. . Further, when the final horizontal drive signal hn is taken out as described above, for example, in a configuration in which a scanner circuit is divided as disclosed in JP-A-3-280679, the output at the end is It can be used for extracting the horizontal drive signal hn.

Further, in the above-described device, the level shift circuit 8 is not an essential component, but for example, the signal lines H1 and H
2... Hn and V1, V2... Vm and switching elements S11, S12... Snm and X1, X2.
, Cnm, the liquid crystal display elements C11, C12... Cnm, the horizontal scanner circuit 3 and the vertical scanner circuit 4 are integrated into an integrated circuit, and the sampling and holding circuit 2 is required when the integrated circuit is a separate integrated circuit.

Alternatively, the level shift circuit 8 can be built in any of these integrated circuits.

According to the above-described display device, the display devices are provided in a horizontal and vertical matrix, and at least a horizontal display device is provided in which an arbitrary sampled video signal is sequentially supplied to the display device to perform display. A scanner circuit for sequentially supplying a video signal to the display element in the direction is built in, and means for extracting an arbitrary drive signal from the scanner circuit is provided, and a video signal in a circuit that performs sampling by the extracted drive signal is provided. By controlling the sampling phase, the sampling phase of the video signal can always be set to the optimum state, that is, the adjustment of the sampling phase can be made unadjusted, and a good video signal is always displayed. Is what you can do.

[0035]

Therefore, according to the first aspect of the present invention, an arbitrary driving signal is taken out from the scanner circuit and the sampling phase of the video signal is controlled to always keep the sampling phase of the video signal in an optimum state. That is, the adjustment of the sampling phase can be eliminated, and a good video signal can be always displayed.

Thus, in the conventional apparatus, it is necessary to adjust the sampling phase for each display device, for example, and this phase is gradually changed by the elapsed time or the like. According to the present invention, there is a problem that the phase of the sampling of the horizontal drive signal and the phase of the horizontal drive signal may be inconsistent. However, according to the present invention, these problems can be easily solved.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an example of a display device to which the present invention is applied.

FIG. 2 is a diagram for explaining the operation.

FIG. 3 is a configuration diagram of a conventional display device.

FIG. 4 is a diagram for explaining this.

FIG. 5 is a diagram for explaining this.

FIG. 6 is a diagram for explaining this.

[Explanation of symbols]

H1, H2... Hn... Horizontal signal lines, V1, V2
... Vm ... vertical signal lines, S11, S12 ... Sn
m, X1, X2 ... Xn ... switching element, C11,
C12 ... Cnm ... Liquid crystal display element, 1 ... Video signal input terminal, 2 ... Sampling hold (S / H) circuit, 3 ... Horizontal scanner circuit, 4 ... Vertical scanner circuit, 5 ... Timing generation circuit, 6 ... Buffer Amplifier, 7 ... output terminal,
8 ... Level shift circuit, 9 ... Phase adjustment (φ) means

Claims (4)

[Claims] 1. A display device in which display elements are provided in a horizontal and vertical matrix, and an arbitrary sampled video signal is sequentially supplied to the display elements to perform display, wherein at least the horizontal display elements are provided. A built-in scanner circuit for sequentially supplying the video signal, and means for extracting an arbitrary drive signal from the scanner circuit are provided. The video signal in a circuit for performing the sampling by the extracted drive signal is provided. A display device, wherein a phase of sampling is controlled. 2. The display device according to claim 1, wherein a signal from an arbitrary timing generating circuit is supplied to the scanner circuit, and a signal from the scanner circuit is supplied to a circuit for performing the sampling, and A display device, wherein a sampling phase is controlled. 3. The display device according to claim 1, further comprising a level shift means for adjusting a signal level between the drive signal extracting means and the sampling circuit. . 4. The display device according to claim 3, wherein said level shift means is provided on the same integrated circuit as said scanner circuit or said sampling circuit.